DETERMINATION OF THE VALUE OF TANGENTIAL FORCE FOR THE HALF-TRACK TRACTION VEHICLE WITH RUBBER TRACKS

Kairatolla Abishev; Karlygash Assylova; Asylbek Kassenov; Almagul Baltabekova

doi:10.5937/jaes0-39677

Kairatolla Abishev Toraighyrov University, 64 Lomov str., Pavlodar, Republic of Kazakhstan
Karlygash Assylova Toraighyrov UniversityToraighyrov University, 64 Lomov str., Pavlodar, Republic of Kazakhstan
Asylbek Kassenov Toraighyrov University, 64 Lomov str., Pavlodar, Republic of Kazakhstan
Almagul Baltabekova Toraighyrov UniversityToraighyrov University, 64 Lomov str., Pavlodar, Republic of Kazakhstan

DOI: https://doi.org/10.5937/jaes0-39677

Keywords: traction and transport vehicle, half-track propulsor, tangential tractive force, ground, normal ground pressure

Abstract

Practice shows that with insufficiently high traction qualities of traction vehicles deteriorate its operational properties. At present, extensive research is under way at home and abroad to find inexpensive but highly effective ways and techniques to improve the traction qualities of vehicles. The design of running systems with reduced resistance to movement and slipping will help to significantly increase the productivity of vehicles and reduce fuel consumption. This, in turn, will contribute to greater operational efficiency for traction vehicles. The authors of this study have developed the design of a traction vehicle with a half-tracked propulsor. The objective of the study is to develop a mathematical model for calculating the efficiency of operating a traction vehicle equipped with a half-tracked propulsior with rubber tracks. The proposed mathematical expression takes into account the deformability of the rubber tracks of the propulsor, the uneven distribution of normal pressure along the length of the track, slipping, geometric parameters of the propulsor and the physical and mechanical properties of the soil. Using numerical methods, calculations were carried out to determine the effect of the tangential tractive force on the slipping of a wheeled traction vehicle with a different layout of the running system. The dependences of the amount of slipping on the tangential thrust force are determined. It has been found that with an increase in the traction force, the slipping increases, however, the intensity of growth of a half-tracked propulsor compared to a wheeled propulsor is much lower.

References

Kulyashov, A.P., Kolotilin, V.E. (2003). Environmental friendliness of propellers of transport and technological machines. Moscow: Mechanical Engineering.

Wong, J.Y. (2010). Terramechanics and Off-Road Vehicle Engineering. Second Edition. Elsevier, Oxford, England.

Zabrodsky, V.M., Finleib, A.M., Kutin, L.N., Utkin-Lyubovtsov, O.L. (1986). Tractor running systems. Device, operation, repair. Moscow: Agropromizdat.

Abishev, K.K., Kassenov, A.Zh., Assylova, K.B. (2020). On the issue of choosing the design of a half-track mover of a traction-transport machine. Mechanics and Technologies, vol. 1, no 67, 31-38.

Abishev, K.K., Kassenov, A.Zh., Assylova, K.B. (2021) Design Justification of Half-Track Propulsor of Traction and Transport Vehicle. Lecture Notes in Mechanical Engineering: 7th International Conference on Industrial Engineering, ICIE 2021.Virtual, Online. DOI:10.1007/978-3-030-85230-6_50

Sherov, K.T., Mussayev, M., Usserbayev, M., Magavin, S., Abisheva, N., Karsakova, N., Kuanov, I., Bekzhanov, Y., Myrzakhmet, B. (2022). Investigation of the method of thermal friction turn-milling of high strength materials. Journal of Applied Engineering Science, vol. 20, no 1, 13-18, DOI: https://doi.org/10.5937/jaes0-29546

Sherov, K., Kuanov, I., Imanbaev, Ye., Mussayev, M., Karsakova, N., Mardonov, B., Makhmudov, L. (2022). The Investigation and Improvement of the Hardness of the Clad Surface by Thermal Friction Milling Methods. International Journal of Mechanical Engineering and Robotics Research, vol. 11, no. 10, 784-792. DOI: https://doi.org/10.18178/ijmerr.11.10.784-792

Donenbayev, B., Sherov, K., Mazdubay, A., Sherov, A., Mussayev, M., Gabdyssalyk, R., Ainabekova, S., Taskarina, A., Tussupova, S. (2021). Investigation of the method of processing holes with a rotary cup cutter with surfacing. Journal of Applied Engineering Science, vol. 19, no. 4, 862-867. DOI:10.5937/Jaes0-27504

Dudak, N., Itybaeva, G., Kasenov, A., Mussina, Z., Taskarina, A., Abishev, K. (2019). Multi-flute drill-broach for precision machining of holes. Scientia Iranica. vol. 26, no. 3, 1415-1426. DOI:10.24200/sci.2018.5623.1379.

Kasenov, A.Z., Abishev, K.K., Mazdubay, A.V., Taskarina, A.Z. (2022). Broach for Cylindrical Holes and Slots. Russian Engineering Research, vol. 42, no 7, 698-700. DOI:10.3103/S1068798X22070140

Wang , J., Liu, P., Chin, C., He , G., Song W. (2020). Parametric study on hydro-elasticity characteristics of auto-pitch wing-in-ground effect oscillating foil propulsors. Ocean Engineering, vol. 201. DOI:10.1016/j.oceaneng.2020.107115

Zhou, L., Gao a, J., Cheng, P., Hu, C. (2020). Study on Track-Soil Traction using Discrete Element Method Simulation and Soil Bin Test. AIP Advances 10, vol. 10, issue 7. DOI:10.1063/5.0016448

Du Plessis, H.L.M., Yu, T.. Modelling the traction of a prototype track based on soil-rubber friction and adhesion. Journal of Terramechanics, vol. 43, issue 4, 487-504. Doi:10.1016/j.jterra.2005.07.002

Emelyanov, A.M., Shpilev, E.M. (2011) Increasing the efficiency of using a tractor of traction class 1.4 due to a triangular crawler. Bulletin of the Altai State Agrarian University, vol.12, no. 86, 95-99.

Emelyanov, A.M., Bumbar, I.V., Kandel, M.V., Ryabchenko, V.N. (2003). Tracked sweepers. Fundamentals of theory and structural and technological devices: monograph. Blagoveshchensk: Blagoveshchensk Agricultural University.

Guskov, V.V., Velev, N.N., Atamanov Yu.A. (1988). Tractors: Theory. Moscow: Mechanical Engineering.

Kutkov, G.M. (2013). Tractors and cars. Theory and technological properties. Moscow: Mechanical Engineering.

Zapolsky, V.P. (2006). Investigation of crawler belt parameters: Proceedings of the scientific conference of the Central Research Institute of Mechanization and Electrification of Agriculture. Minsk. 2006, p. 87-92.

Zhao, H., Chen, W., Zhou, S., Liu, Y.-H. (2021). Parameter Estimation of an Industrial Car-Like Tractor. IEEE Robotics and Automation Letters, vol. 6, no. 3, 4480-4487. DOI:10.1109/LRA.2021.3068943

Tadakuma, K., Ogata, H., Tadakuma, R., Berengueres, J. (2014). Torus Omnidirectional Driving Unit Mechanism Realized by Curved Crawler Belts: 2014 IEEE International Conference on Robotics and Automation (ICRA), DOI:10.1109/ICRA.2014.6907224

Platonov, V.F. (1973). Dynamics and reliability of the crawler engine. Moscow: Mechanical Engineering.

Abishev, K.K., Kasenov">https://www.scopus.com/authid/detail.uri?authorId=56242829800&eid=2-s2.0-85030862872">Kasenov, A.Zh., Assylova, K.B., Gumarov, G.S. Study of the Interaction of a Transport Vehicle with an Open Road. Lecture Notes in Intelligent Transportation and Infrastructure. 154-163. DOI: 10.1007/978-3-030-39688-6_21

Kassenov, A.Zh. Abishev, K.K., Absadykov, B.N., Yessaulkov, V.S., Bolatova, A.B. (2022). Analysis and justification of the layout of a multipurpose machine for the development of mineral deposits. News of the National Academy of Sciences of the Republic of Kazakhstan, Series of Geology and Technical Sciences. vol. 1, no. 451, 63-68. DOI:10.32014/2022.2518-170X.141

Abishev, K.K., Kassenov, A.Zh., Mukanov, R.B., Sembaev, N.S., Suleimenov, A.D. (2021). Research on the Operational Qualities of a Mining machine for the development of mineral deposits. News of the National Academy of Sciences of the Republic of Kazakhstan, Series of Geology and Technical Sciences, vol. 6, no. 450, 30-36. DOI:10.32014/2021.2518-170X.116